[0001] The invention relates to a balloon catheter comprising a tube-like basic body with
a proximal and a distal end. A balloon-shaped member has been arranged at the distal
end, and this balloon-shaped member can be expanded by supplying medium under pressure
to it via a lumen in the basic body. At both ends the balloon member is connected
with the basic body in a sealed manner. In a section enclosed by the balloon member
and positioned in between these sealed connections, at least one opening has been
arranged in the wall of the basic body in order to be able to supply the medium under
pressure from the lumen to the inside of the balloon member and to remove it from
there.
[0002] The expansion possibilities of the balloon are limited by the fact that an expansion
in radial direction has to be accompanied by a reduction in axial direction. The ends
of the balloon member are however fixed to the basic body, so that with the catheters
manufactured according to the current state of the technique, axial reduction is not
possible.
[0003] With the catheter according to the invention a number of elongated openings, extending
in a longitudinal direction, have been arranged in the wall of the section of the
basic body enclosed by the balloon member. In between these openings strip-shaped
elements, which can bend outwards, remain. Due to this bending outwards the enclosed
section can be reduced axially, as a result of which the balloon member can expand
freely. On supplying medium under pressure an axial compressive force is exerted on
the enclosed section due to the radial expansion, whereby the ends thereof are forced
towards each other and, as a result of this compressive force, the strip-shaped sections
will bend outwards from in between the openings.
[0004] In the non-expanded state of the balloon the strip-shaped parts in between the openings
are straight, as a result of which they can withstand sufficient compressive force
which is generated when introducing a balloon catheter into a patient.
[0005] By employing the measures according to the invention the balloon member can, in non-expended
state, have a small diameter and can be positioned tightly against the basic body.
In the expanded state such a balloon can have a large effective diameter.
[0006] In order to obtain a suitable bending performance the measure as set out in claim
2 is preferably employed. The strip- shaped wall sections bend outwards uniformly
around the entire circumference, as a result of which the longitudinal axis of the
balloon remains in line with the catheter. The balloon will not be pulled out of position
on expansion.
[0007] According to a further development the measure as set out in claim 3 is employed.
Consequently the entire axial reduction is spread over the different groups, so that
the strip-shaped sections in between each group of openings need to be subjected to
only relatively little deformation and do not bend outwards too much.
[0008] A suitable embodiment is characterised in claim 4. In this way sufficient deformation
is combined with a suitable stiffness. By employing the measure as set out in claim
5, the cross-section of the strip-shaped sections becomes practically flat, so that
they bend outwards easily and spring back into their original shape again.
[0009] The catheter according to the invention is preferably manufactured as characterised
in claim 6.
[0010] In case the catheter according to the invention is provided with a tube-like element
which extends inside the lumen of the basic body, the intended use of which tube-like
element is for instance supplying contrast medium to the distal end of the catheter,
the measure as set out in claim 7 is preferably employed.
[0011] The invention can be employed particularly well with the measure as set out in claim
8. The shape of the expanded balloon can be determined carefully in advance, while
the significant axial reduction occurring during expansion can be absorbed well.
[0012] The invention will be explained in greater detail in the following description with
reference to the attached drawings.
[0013] Figure 1 shows a distal end-section of the catheter according to the invention with
the balloon member in non- expanded state.
[0014] Figure 2 shows a view corresponding to that of figure 1 of the distal end-section
of the catheter of figure 1 with the balloon in expanded state of use.
[0015] The distal end-section of a catheter 1 illustrated in fig. 1 shows the basic body
2 of that catheter on which a balloon-shaped element 3 has been arranged. At the right
end 4 and left end 5 as seen in fig. 1, the balloon member 3 has been connected with
the basic body 2 in a sealed manner. The left end 5 of the balloon is connected with
a separate end-section 8 at the same longitudinal position as the end of the basic
body 2. In this end-section 8 a canal 9 has been formed to which for instance contrast
medium can be supplied via a separate inner tube-like element 7 which has been received
in the lumen 10 of the basic body 2. The inner tube-like element 7 is connected with
the end-section 8 at the same height as the end 5 of the balloon member 3 and the
end of the basic body 2.
[0016] In the illustrated example of the embodiment two groups of elongated openings 12
and 13 respectively, extending in a longitudinal direction, have been formed inside
the section 6 of the basic body 2 enclosed by the balloon member 13. Of each group
the openings 12 and 13 respectively have been arranged equally divided around the
circumference, each time over the same longitudinal distance. Each time strip-shaped
sections 16, which can bend outwards relatively easily, are defined in between the
openings 12, 13, as can be seen in fig. 2. This bending outwards occurs when medium
under pressure is supplied via the lumen 10 of the basic body 2. This medium flows
via the openings 12, 13, into the balloon member 3 which consequently expands. On
expansion the axial length reduces from the size indicated with number 14 in fig.
1 to the size indicated with number 15 in fig. 2. This reduction in length is possible
as the strip-shaped sections bend outwards as can be seen clearly in fig. 2.
[0017] After allowing the medium under pressure to flow away, the catheter tip will resume
the shape shown in fig. 1 as a result of the elasticity of the strip-shaped section
16.
[0018] The balloon-shaped member 3 has been made of a relatively inelastic material, so
that the shape of the balloon-shaped member 3 in the expanded state is substantially
predetermined. In the non-expanded state the material of which the balloon-shaped
member has been made is folded in pleads against the basic body 2. This has not been
illustrated in detail in fig. 1; however, this method of folding a balloon-shaped
member is as such known from the current state of the technique. Because of the size
of the openings, the material can be folded in such a way that the non-expanded diameter
is relatively small.
1. Catheter comprising a tube-like basic body with a proximal and a distal end and with
at least one lumen defined by a wall, wherein a balloon member has been arranged at
the distal end which, on both ends of an enclosed section of the basic body, is connected
to the basic body in a sealed manner and wherein, in the enclosed section a number
of elongated openings, extending in a longitudinal direction, have been formed in
the wall.
2. Catheter as claimed in claim 1, wherein the openings of at least one group have been
arranged over the same longitudinal distance and are equally divided around the circumference.
3. Catheter as claimed in claim 2, wherein the openings have been arranged in at least
two, in a longitudinal direction, successive groups, wherein, in between adjoining
groups, there is a section of the basic body which is free of openings.
4. Catheter as claimed in claim 2 or 3, wherein each group comprises three openings.
5. Catheter as claimed in claim 4, wherein each opening is wider than the material of
the basic body remaining in between adjoining openings of a group.
6. Catheter as claimed in one of the previous claims, wherein the distal end of the basic
body and the relatively distal end of the balloon member are connected at the same
longitudinal position with an end-section of a catheter.
7. Catheter as claimed in claim 6, wherein a tube-like element has been received inside
the lumen of which the distal end is connected with the end-section at the same longitudinal
position as the basic body.
8. Catheter as claimed in one of the previous claims, wherein the balloon member has
been made of relatively inelastic material.